1. Granada, October 2007 Marc Davis UC Berkeley The DEEP2 Redshift Survey

2. The DEEP2 Collaboration U.C. Berkeley M. Davis (PI) D. Croton M. Cooper B. Gerke R. Yan U.C. Santa Cruz S. Faber (Co-PI) D. Koo P. Guhathakurta U.C. Santa Cruz D. Phillips S. Kassin K. Noeske A. Metevier L. Lin N. Konidaris G. Graves J. Harker Other Institutions J. Newman (LBNL) A. Coil (Arizona) C. Willmer (Arizona) B. Weiner (Arizona) R. Schiavon (UVA) C. Conroy (Princeton) N. Kaiser (Hawaii ) D. Finkbeiner (Harvard) A. Connolly (Pitt.) The DEEP2 Galaxy Redshift Survey used the DEIMOS spectrograph at the Keck II telescope to study both galaxy properties and large-scale structure at z~1.

3. Granada, October 2007 DEEP2 has been made possible by DEIMOS, a new instrument on Keck II DEIMOS: PI: Faber wide-field multiplexing (up to 160 slitlets over a 16’x4’ field) high resolution (R~5000) spectral range (~2600 Å at highest resolution) CCD array of 8k x 8k

4. Optics are key to the success of DEIMOS Complex design by Harlan Epps Brilliant work by Dave Hilyard

5. Granada, October 2007 DEEP2 pre-selects high-z galaxies using observed colors

6. DEEP2 mask selection Targeted galaxies are enclosed with white curves Solid slits are objects selected on a given mask. dotted and dashed lines are galaxies from neighboring masks.

7. Granada, October 2007 DEEP2 slitmask spectroscopy Using custom-milled slitmasks with DEIMOS we obtained spectra of ~150 targets at a time. A total of 400 slitmasks was required for the survey; we tilted slits up to 30 degrees to obtain rotation curves. position

8. Granada, October 2007 AEGIS: the All-wavelength Extended Groth Strip International Survey Spitzer MIPS, IRAC DEEP2 spectra and Caltech/JPL K s imaging HST/ACS V,I (Cycle 13) DEEP2/CFHT B,R,I GALEX NUV+FUV Chandra & XMM: XMM Chandra (1.6Ms) Plus VLA (6 & 21 cm), SCUBA, etc….

9. Granada, October 2007 X-ray analysis - detection and photometry P.Nandra et al. Each square has integration time of 200 ksec Source selection and photometry by own method –Elliptical shaped PSFs All data will be released in August, 2007 1.6 Ms

10. Granada, October 2007 Comparison with Other Surveys z~0 z~1 DEEP2 SDSS 2dF CFA+ SSRS LCRS PSCZ DEEP2 -- comparable in size and density to previous generation local redshift surveys >50 times larger than previous surveys at z~0.3-1. DEEP2 is similar to LCRS in sample size but at z=1 - with a very different geometry: ~20  80  1000 h -3 Mpc 3 per field (LCDM)

11. Granada, October 2007 A Redshift Survey at z=1: 3 sq. degrees 4 fields (0.5 o x <2 o ) 80 Keck nights, one-hour exposures to R AB =24.1 primarily z~0.75-1.4 ( pre-selected using BRI photometry ) 47,000 unique redshifts, error ~30 km/s ~5·10 6 h -3 Mpc 3 1200 l/mm: ~6500-9200 Å 1.0” slit: FWHM  68 km/s z=0.7-1.4 spans lookback time ~6.0 - 8.0 Gyr ago Within DEEP2 we are surveying 2.5 Gyr or ~20% of the history of the Universe, and SDSS/2dF comparisons give ~3x this baseline

12. Granada, October 2007 Redshift Distribution of DEEP2 Survey

13. Granada, October 2007 DEEP2 Status Update DEEP2 began observations in July 2002. Observations are now >99% finished, with >49k spectra in hand and 3 of 4 fields completed. Follow-up observations have begun. ALL the data is already public: http://deep.berkeley.edu/DR4 The catalog and 2d spectra is all available, and others are releasing Chandra, Spitzer, GALEX, HST, ….

14. Granada, October 2007 Brian F. Gerke Evrard et al. 02 Hubble volume simulations ΛCDM  CDM o 10 15 M o * 10 14.5-15 M o. 10 14-14.5 M o =1 =0.3,  Λ  =0.7 Cluster abundance depends on cosmology

15. Granada, October 2007 2PIGG:Ek e et al 2004 DEEP2: Gerke et al 2005 z=0.75 z=1.0

16. Granada, October 2007 Redshift Maps in 4 Fields: z=0.7-1.3 Cone diagram of 1/12 of the full DEEP2 sample

17. Granada, October 2007 Galaxy groups in DEEP2, z position Overdensities identified in redshift space. Use the VDM algorithm of Marinoni et al. (2002). Group in early DEEP2 data s~250 km/sec

18. Granada, October 2007 DEEP2 Group Catalog Gerke et al. 2005, astro-ph/0410721 Shown are groups for 3 fields --length of ellipse proportional to velocity dispersion Groups with  >350 km/s

19. Looking for DEEP2 groups in the X-ray 200 ks Chandra observation in the Extended Groth Strip (1/8 of total coverage), with positions of 7 DEEP2 groups superimposed (2 300 km/s) T. Fang et al, 2006, in press

20. Granada, October 2007 Real Groups/Mock Groups x-r redshift plot y-r redshift plot X-y projected on sky galaxies shown in 3 projections Real or Mock???

21. Why search for groups in DEEP2? Apparent abundance of groups: dN( ,z)/dzd  Provides a useful test of dark energy eq. of state (Newman et al, 2002) differences in the volume element varies by 3x between w=0 and w=-1 For groups of modest-mass, the evolution of dispersion is 2nd order Heavy black curve is  T =.3 DEIMOS took ~7 years to build; at time of designing science expt.  T was still undetermined, and DE was not discussed.

22. Size of the Universe versus w

23. Abundance versus Redshift Simulated Data!! Gerke etal 2008

24. Measured dispersion with galaxies compared to reality -- tremendous scatter!

25. Granada, October 2007 Dispersion with galaxies

26. Granada, October 2007 Brian F. Gerke We can reconstruct the quantity we need with the VDM Successful above ~350 km/s We want to measure N(σ, z) to constrain cosmology. Tests on the mock catalogs indicate that we can measure N(σ,z) in DEEP2 accurately for σ>350 km/s.

27. Granada, October 2007 Brian F. Gerke Projected constraints Computed with DM halos in simulated DEEP2 and 2dF light cones, constructed from the Millennium Run. In each panel, the suppressed parameter is held fixed. input cosmology

28. DEEP2 Cluster Counts DEEP2 survey counted ~300 groups Velocity dispersion measured in each case Counts of N( , z) is a strong test of w Have not got mock catalogs with the evolving color selection, making it difficult to proceed B. Gerke will have results out “soon”

29. Measuring Kaiser infall in  (r p,  ) The blue galaxies show fully developed coherent infall pattern on scales >5 Mpc, as expected. The red galaxies have very extended fingers of god, as expected. Coil et al, 2008

30. Kaiser infall, MOCKS Millenium mocks, not a bad approximation Coil et al, 2008

31. Granada, October 2007 By combining area with depth, AEGIS allows us to study rare objects in detail… B. Gerke, JN et al. 2006, AEGIS ApJL, Accepted

32. Granada, October 2007 Like a spectroscopically identified, dual AGN at z=0.7 HH [OIII] 4959 [OIII] 5007 / z position

33. Granada, October 2007 HST reveals a fairly-normal early-type host

34. Granada, October 2007 AEGIS gives its SED over 9 decades in

35. Granada, October 2007 Advantages of a high-dispersion survey The high resolution used for DEEP2 observations yields well-resolved linewidths for all objects, and rotation curves as a free byproduct for thousands. Shown are four 2d spectra exhibiting resolved [OII] emission and the derived circular velocity V c (r). Cooper et al. 2004

36. Rotation Curves of 88 galaxies with HST and DEIMOS’s Spatial Resolution Study evolution of Spirals Metevier et al, 2007, in process

37. Ly-alpha emission seen in many slits Slits are 1” long, more than 50% blank field, giving > 1 sq arcminute for deep search, 3 < z < 6 Searching by “eye” for asymmetric emission lines So far they have searched ~20% of fields and found 9 clean systems Sawicki et al, in preparation

38. Granada, October 2007 DEEP2 observations are >99% done Work not yet published is study of galaxy clustering DR4 has occurred this August: http://deep.berkeley.edu/DR4 AEGIS ApJL special issue Way too many new results to cover in one talk! A Spectroscopic survey has many followups! Conclusions on DEEP2